Medicine I Neurophysiology Lecture Notes 2024 PDF

Summary

This document is a lecture on neurophysiology, focusing on the central nervous system. It explores topics like neurons, neuroglia, and the protection of the CNS. This lecture is part of "Medicine I" and is for undergraduate students.

Full Transcript

THE CENTRAL
NERVOUS
SYSTEM
 LECTURER INFORMATION

Mrs M van Hoogland-van Heerden

BMS Building 4th Floor

Room: N412

Office number: 012 521 4332

Email: [email protected]
NERVOUS SYSTEM ORGANISATION

Important:
How
everything
fits together
in the bigger
picture
FUNCTIONAL CLASSES OF NEURONS
Afferent neurons
Inform the CNS about conditions in both the internal and
external environment
At its peripheral ending there is a sensory receptor that
generates action potentials in response to stimulus

Efferent neurons
Carry instructions from CNS to effector organs, muscles
and glands
Lie primarily in the PNS

Interneurons (Most abundant)
Found entirely in the CNS
Lie between afferent and efferent neurons
Responsible for:
 Integrating afferent information and formulating an
efferent response
 Interconnections between interneurons are associated
with higher mental functions
NEUROGLIA
Neuroglia/Glial Cells
Unlike neurons neuroglia/glial cells do not initiate or
conduct nerve impulses
Neuroglia/glial cells do communicate with neurons and
among themselves via chemical signals
Serve as connective tissue of the CNS
Support interneurons physically, functionally and
metabolically

4 Types of Neuroglia/Glial cells
Know the
1. Astrocytes functions of each
2. Oligodendrocytes type of glial cell –
3. Microglia refer to table on
4. Ependymal cells next slide
 FUNCTIONS OF NEUROGLIA
GLIAL CELL TYPE FUNCTIONS
Astrocytes Most abundant glial cell type and act as the main ‘glue’ of the CNS (Holding neurons together)
Serve as a scaffold that guides neurons during fetal brain development
Responsible for the formation of the BBB (Induce capillary changes both anatomical/functional)
Helps with transfer of nutrients from the blood to the neurons
Brain injury repair by forming neural scars
Take up/degrade locally released NTs (Bringing chemical messenger actions to a halt):
Glutamate and GABA
Take up excess K+ from the brain ECF (Excitability) * Refer back to action potentials
Extracellular communication with neurons and via jap junctions * Refer to textbook
Enhance synapse formation and modify synaptic transmission

Oligodendrocytes Insulative myelin sheaths around the axons in the CNS
Later in fetal life – Nerve growth inhibiting proteins (Nogo)
Microglia Immune defence cells of the CNS (stationary until activated by infections/injuries)
Release destructive chemicals for assult against foreign invaders
Nerve growth factor release in resting state (helps neurons and glial cells survive)
Ependymal Line the internal, fluid filled cavities of the CNS
Help to form CSF
Neural stem cells (Able to form other types of glial cells and neurons)
 NEUROGLIA
MENINGIOMAS
(Tumour of the meninges which are the covering of the brain and the
spinal cord)
The most common kind of brain tumour
Mostly benign
Does not infltrate the brain but can exert pressure on the
brain

NON-NEURAL TUMOURS NEURAL TUMOURS
PROTECTION OF THE CNS

Enclosed by hard, bony structures
 Cranium (Skull) (brain)
 Vertebral column (spinal cord)

Wrapped by 3 protective and nourishing
membranes- meninges
 Dura mater
 Arachnoid mater
 Pia mater

Brain floats in cushioning fluid – CSF

BBB limits access of blood-borne materials into
brain tissue
 CSF COMPOSITION

CSF has the same density as the brain
CSF is lower in potassium compared to blood
CSF has a slightly higher sodium content than blood
Necessary for the movement of ions down concentration gradients
Almost no proteins in CSF (Plasma proteins cannot exit the brain capillaries to leave the blood during the
formation of CSF)
125mL – 150mL (replaced more than 3x per day)
CSF (FUNCTION)
Surrounds and cushions the brain and spinal cord

Major function: Serves as a shock-absorbing fluid to
prevent the brain from bumping against the hard skull

Other functions:
 Exchange of materials between neural cells and
interstitial fluid surrounding the brain
 Formed primarily by choroid plexuses
 Richly vascularised masses of pia mater tissue
that dip into pockets formed by ependymal cells
 CSF forms as a result of selective transport
mechanisms across membranes of choroid plexuses
CSF CONDITIONS
Hydrocephalus: Excess CSF
- Causes increased CSF pressure
- Brain damage can occur (mental retardation)
- Treatment: Surgical shunting to drain excess CSF to veins
 BBB
Highly selective

Protects the brain from chemical fluctuations in the blood

 Strictly limits exchange between blood and brain

Minimizes the possibility that harmful blood-borne substances

might reach the central nervous tissue

Prevents certain circulating hormones that could also act as NTs

from reaching the brain

Limits the use of drugs for the treatment of brain and spinal cord

disorders as many drugs cannot penetrate the BBB
 BBB

Certain areas of the brain (portion of the Hypothalamus) are not subject to the BBB

“sampling of blood” to make appropriate adjustments (homeostasis)

Output – in the form of water soluble hormones that must enter the hypothalamic capillaries

Hypothalamic capillaries are not sealed by tight junctions

4 areas of the brain are not protected by the BBB. These areas include the posterior pituitary gland,

pineal gland, the median eminence of the hypothalamus and the area postrema
 O2 & GLUCOSE

The brain depends on constant delivery of oxygen and glucose by the blood

The brain cannot produce ATP in the absence of oxygen (metabolism)

Neuroglobin (oxygen binding protein in the brain)

Brain primarily uses glucose for energy (starvation – ketone bodies produced by the liver)

Resting: 20% of oxygen and 50% glucose

15% of blood pumped out by the heart
 BRAIN DAMAGE
Oxygen / glucose deprivation

More than 4-5 min without oxygen

More than 10-15 min without glucose

Common cause: Stroke

Treatment option: clot dissolving drugs
FUNCTIONS OF THE CNS

CNS consists of the brain and the spinal cord
CNS enables you to:
 Subconsciously regulate your internal environment by
neural means
 Experience emotions
 Voluntarily control your movements
 Be consciously aware of your own body and your
surroundings
 Engage in other higher cognitive processes such as
thought and memory
ANATOMY OF THE BRAIN

Forebrain
Diencephalon
- Thalamus
- Hypothalamus
Cerebrum
- Basal nuclei
- Cerebral cortex
 FUNCTIONS OF THE BRAIN COMPONENTS
n t
rta n s
p o ti o
Im nc
fu
BRAIN STEM

Oldest region of the brain
Continuous with spinal cord
Controls many life-sustaining processes, such as respiration,
circulation, and digestion
Concerned with maintaining proper position of the body in
space and subconscious coordination of motor activity
(movement)
Consists of the midbrain, pons and medulla
CEREBELLUM
Subcortical* region of the brain
Attached at top rear portion of the brain stem
Important role in planning, initiating, and timing of
movements by sending input to the motor areas of
the cortex
Maintains proper position of the body in space
Subconscious coordination of motor activity
(movement)
Plays a key role in learning skilled motor tasks

*Subcortical: Below the cortex
DIENCEPHALON
CONSISTS OF 2 BRAIN COMPONENTS:
 Thalamus
 Performs primitive sensory processing
 Serves as a relay station
 Screens out insignificant signals and routes
important sensory impulses to appropriate areas
 Helps to direct attention to stimuli of interest
 Hypothalamus
 Controls many homeostatic functions
 Plays a role in emotional and behavioural
patterns
 Regulation of the internal environment
 CEREBRUM
Cerebrum
Corpus Callosum
Highly developed
80% of total brain weight
Divided into 2 halves:
 R and L Cerebral hemispheres (connected via the
Corpus Callosum)
Inner core houses the basal ganglia
Outer surface is highly convoluted cerebral cortex
 Caps inner core that houses basal nuclei
 Highest, most complex integrating area of the brain
 Plays key role in most sophisticated neural functions

Pons Cerebellum Highest, most complex integrating area of the brain
Medulla
 CEREBRAL CORTEX
Thin outer shell of grey matter that covers each hemisphere

Covers a thick central core of white matter

Cerebral Organised into 6 well defined layers
Cortex
Layers are organised into functional vertical columns

Each half of cortex divided into 4 major lobes:

 Occipital

 Temporal

 Parietal

 Frontal
CEREBRAL CORTEX (4 LOBES)
OCCIPITAL LOBE
 Carries out initial processing of visual input
TEMPORAL LOBE
 Initial reception of auditory (sound) sensation
PARIETAL LOBE
 Receive and process sensory input
 Somatosensory processing
FRONTAL LOBE
 Responsible for 3 main functions:
 Voluntary motor activity
t
 Speaking ability r t an
po ns
Im c t io
 Elaboration of thought fun
CEREBRAL CORTEX (LANGAUGE AREAS)

Primary areas of cortical specialisation for language
 Broca’s area (speaking)
 Wernicke's area (language comprehension)
Language disorders
 Aphasias (mostly due to stroke)
 Speech impediments (defect in the mechanical
aspect of speech – vocal cords)
 Dyslexia (inappropriate interpretation of words)
BASAL NUCLEI (BASAL GANGLIA)

Consists of several masses of grey matter located deep
within the white matter
Act by modifying ongoing activity in motor pathways
Primary functions:
 Inhibiting muscle tone throughout the body
 Selecting and maintaining purposeful motor activity
while suppressing useless or unwanted patterns of
movement
 Helping to monitor and coordinate slow, sustained
contractions (posture)
 PARKINSON’S DISEASE

Associated with a gradual destruction of neurons that release the NT

Dopamine (Basal nuclei)

3 Types of motor disturbances:

 Increase in muscle tone, or rigidity

 Involuntary, useless, or unwanted movements such as resting tremors

 Slowness in initiating and carrying out different motor behaviours

Treat with L-Dopa (precursor of dopamine) – BBB
THALAMUS
Positively reinforces voluntary motor behaviour initiated by

the cortex

Part of the diencephalon

Serves as a ‘relay station’ and synaptic integrating center for

processing sensory input on its way to cerebral cortex

Along with brain stem and cortical association areas, important

in ability to direct attention to stimuli of interest

Capable of crude awareness of various types of sensation

but cannot distinguish their location or intensity
HYPOTHALAMUS

Brain area most involved in directly regulating internal
environment
Functions:
 Controls body temperature
 Controls thirst and urine output
 Controls food intake
 Controls anterior pituitary hormone secretion
 Influence sleep-wake cycle
 Plays a role in emotional and behavioural patterns
 Many more functions … (Refer to textbook)
LIMBIC SYSTEM
Not a separate structure but a ring of forebrain
structures that surround the brain stem
Includes portions of the hypothalamus and other
forebrain structures that encircle the brain stem
Responsible for:
 Emotion
 Basic, inborn behavioural patterns related to
survival and perpetuation of the species
 Plays important role in motivation and learning

Self-study: Reward vs punishment, motivation and
homeostatic drives p125
CEREBELLUM
Important in balance and in planning and executing voluntary
movement
3 DIFFERENT PARTS
 Vestibulocerebellum
 Important in maintaining balance and controls eye
movements
 Spinocerebellum
 Enhances muscle tone and coordinates skilled,
voluntary movements
 Cerebrocerebellum
 Plays a role in planning and initiating voluntary
activity by providing input to cortical motor areas
 Stores procedural memories
BRAIN STEM

Critical in connecting the link between spinal cord and
higher brain regions
Oldest region of the brain
Continuous with spinal cord
All incoming and outgoing fibers transversing between
periphery and higher brain centers must pass the brain
stem
Consists of:
 Medulla
 Pons
 Midbrain
ANATOMY OF THE SPINAL CORD/ NERVES

Extends from brain stem through vertebral canal
31 pairs of spinal nerves emerge from spinal cord
through spaces formed between arches of adjacent
vertebrae
 Named for region of vertebral column from which
they emerge
 8 pairs cervical (neck) nerves
 12 pairs thoracic (chest) nerves
 5 pairs lumbar (abdominal) nerves
 5 pairs sacral (pelvic) nerves
 1 pair coccygeal (tailbone) nerves
FUNCTIONS OF THE SPINAL CORD

2 Vital functions
 Neuronal link between brain and PNS
 Integrating center for spinal reflexes
THE PERIPHERAL
NERVOUS
SYSTEM
PNS: EFFERENT DIVISION

Communication link by which CNS controls activities
of muscles and glands
Two divisions of PNS
 ANS
 Involuntary branch of PNS
 Innervates cardiac muscle, smooth muscle,
most exocrine glands, some endocrine glands,
and adipose tissue
 Somatic nervous system
 Subject to voluntary control
 Innervates skeletal muscle
 ANS
Autonomic nerve pathway
 Extends from CNS to an innervated organ
Two-neuron chain
 Preganglionic fiber (synapses with cell body of second neuron)
 Postganglionic fiber (innervates effector organ)

BASIC STRUCTURE: IMPORTANT
 ANS
Two subdivisions of the ANS:
Kn
Sympathetc nervous system ow
tab this
Parasympathetc nervous system le

Sympathetic Nervous System Parasympathetic Nervous System
Fibers originate in thoracic and lumbar regions of the Fibers originate from cranial and sacral areas of CNS
spinal cord
Most preganglionic fbers are short Preganglionic fbers are longer

Long postganglionic fbers Very short postganglionic fbers

Preganglionic fbers release Ach Preganglionic fbers release Ach

Most postganglionic fbers release noradrenaline Postganglionic fbers release Ach
ANS
 ANS
Most visceral organs are innervated by both
sympathetic and parasympathetic fibers
In general produce opposite effects in a particular organ
Dual innervation of organs by both branches of ANS
allows precise control over organ’s activity
Sympathetic system: Dominates in emergency or
stressful (‘fight-or-flight’) situations
Promotes responses that prepare the body for
strenuous physical activity
Parasympathetic system: Dominates in quiet, relaxed
(‘rest-and-digest’) situations
Structures innervated by Promotes body-maintenance activities
sympathetic and parasympathetic
nervous systems
 ADVANTAGE OF DUAL INNERVATION

1. Innervated blood vessels: receive only sympathetic nerve fibers (most arterioles and veins)

Accomplished by decreasing or increasing the firing rate above/below tone level in these fibers

*Only blood vessels that have both sympathetic/parasympathetic fibers are those supplying the penis

and clitoris

2. Sweat glands: innervated only by sympathetic nerves

Postganglionic fibers secrete Ach instead of NE

3. Salivary glands: innervated by both sympathetic and parasympathetic activity that is not antagonistic

Both stimulates salivary secretion (volume, composition differs)
 NEUROTRANSMITTER RECEPTORS

Tissues innervated by the ANS have one or more of several different receptor types for postganglionic

chemical messengers

 Cholinergic receptors – bind to Ach

 Nicotinic receptors – found on postganglionic cell bodies of all autonomic ganglia

 Muscarinic receptors – found on effector cell membranes

 Adrenergic receptors – bind to norepinephrine and epinephrine

 Alpha (α) receptors

 Beta (β) receptors
 ANS

Adrenal medulla is a modified part of the sympathetic nervous system

 Modified sympathetic ganglion that does not give rise to postganglionic fibers

 Stimulation of preganglionic fiber prompts secretion of hormones into blood

 About 20% of hormone release is norepinephrine

 About 80% of hormone release is epinephrine
ANS
Exceptions to general rule of dual
reciprocal innervation by the two branches
of autonomic nervous system
 Most arterioles and veins receive only
sympathetic nerve fibers (arteries and
capillaries are not innervated)
 Most sweat glands are innervated only by
sympathetic nerves
 Salivary glands are innervated by both
ANS divisions but activity is not
antagonistic – both stimulate salivary
secretion
 AUTONOMIC AGONISTS AND ANTAGONISTS

Agonists Drugs that act selectively at α- and β-
 Bind to same receptor as neurotransmitter adrenergic receptor sites
 Elicit an effect that mimics that of  Salbutamol: Selectively activates β2-
neurotransmitter adrenergic receptors at low doses. (Dilates
Antagonists bronchioles for asthma)
 Bind with receptor  Metoprolol: Selectively blocks β1-
 Block neurotransmitter’s response adrenergic receptors (BP medication)
 SOMATIC NERVOUS SYSTEM

Consists of axons of motor neurons that originate in spinal cord or brain stem and end on

skeletal muscle

Motor neuron releases neurotransmitter, Ach, which stimulates muscle contraction

Motor neurons are final common pathway by which various regions of CNS exert control

over skeletal muscle activity

 These areas of CNS include spinal cord, motor regions of cortex, basal nuclei,

cerebellum, and brain stem
 SOMATIC NERVOUS SYSTEM
The cell bodies of motor neurons may be selectively destroyed by polio virus – Paralysis

ALS / Lou Gehrig’s disease is the most common motor neuron disease – Degeneration /

death of motor neurons (progressive disease with death 3-5 years after onset)